src/tools/miri/src/eval.rs - toolchain/rustc - Git at Google

 //! Main evaluator loop and setting up the initial stack frame.

 use std::ffi::{OsStr, OsString};
 use std::iter;
 use std::panic::{self, AssertUnwindSafe};
 use std::path::PathBuf;
 use std::task::Poll;
 use std::thread;

 use crate::concurrency::thread::TlsAllocAction;
 use crate::diagnostics::report_leaks;
 use rustc_data_structures::fx::FxHashSet;
 use rustc_hir::def::Namespace;
 use rustc_hir::def_id::DefId;
 use rustc_middle::ty::{
     self,
     layout::{LayoutCx, LayoutOf},
     Ty, TyCtxt,
 };
 use rustc_target::spec::abi::Abi;

 use rustc_session::config::EntryFnType;

 use crate::shims::tls;
 use crate::*;

 /// When the main thread would exit, we will yield to any other thread that is ready to execute.
 /// But we must only do that a finite number of times, or a background thread running `loop {}`
 /// will hang the program.
 const MAIN_THREAD_YIELDS_AT_SHUTDOWN: u32 = 256;

 #[derive(Copy, Clone, Debug, PartialEq)]
 pub enum AlignmentCheck {
     /// Do not check alignment.
     None,
     /// Check alignment "symbolically", i.e., using only the requested alignment for an allocation and not its real base address.
     Symbolic,
     /// Check alignment on the actual physical integer address.
     Int,
 }

 #[derive(Copy, Clone, Debug, PartialEq)]
 pub enum RejectOpWith {
     /// Isolated op is rejected with an abort of the machine.
     Abort,

     /// If not Abort, miri returns an error for an isolated op.
     /// Following options determine if user should be warned about such error.
     /// Do not print warning about rejected isolated op.
     NoWarning,

     /// Print a warning about rejected isolated op, with backtrace.
     Warning,

     /// Print a warning about rejected isolated op, without backtrace.
     WarningWithoutBacktrace,
 }

 #[derive(Copy, Clone, Debug, PartialEq)]
 pub enum IsolatedOp {
     /// Reject an op requiring communication with the host. By
     /// default, miri rejects the op with an abort. If not, it returns
     /// an error code, and prints a warning about it. Warning levels
     /// are controlled by `RejectOpWith` enum.
     Reject(RejectOpWith),

     /// Execute op requiring communication with the host, i.e. disable isolation.
     Allow,
 }

 #[derive(Copy, Clone, PartialEq, Eq)]
 pub enum BacktraceStyle {
     /// Prints a terser backtrace which ideally only contains relevant information.
     Short,
     /// Prints a backtrace with all possible information.
     Full,
     /// Prints only the frame that the error occurs in.
     Off,
 }

 /// Configuration needed to spawn a Miri instance.
 #[derive(Clone)]
 pub struct MiriConfig {
     /// The host environment snapshot to use as basis for what is provided to the interpreted program.
     /// (This is still subject to isolation as well as `forwarded_env_vars`.)
     pub env: Vec<(OsString, OsString)>,
     /// Determine if validity checking is enabled.
     pub validate: bool,
     /// Determines if Stacked Borrows or Tree Borrows is enabled.
     pub borrow_tracker: Option<BorrowTrackerMethod>,
     /// Whether `core::ptr::Unique` receives special treatment.
     /// If `true` then `Unique` is reborrowed with its own new tag and permission,
     /// otherwise `Unique` is just another raw pointer.
     pub unique_is_unique: bool,
     /// Controls alignment checking.
     pub check_alignment: AlignmentCheck,
     /// Action for an op requiring communication with the host.
     pub isolated_op: IsolatedOp,
     /// Determines if memory leaks should be ignored.
     pub ignore_leaks: bool,
     /// Environment variables that should always be forwarded from the host.
     pub forwarded_env_vars: Vec<String>,
     /// Command-line arguments passed to the interpreted program.
     pub args: Vec<String>,
     /// The seed to use when non-determinism or randomness are required (e.g. ptr-to-int cast, `getrandom()`).
     pub seed: Option<u64>,
     /// The stacked borrows pointer ids to report about
     pub tracked_pointer_tags: FxHashSet<BorTag>,
     /// The stacked borrows call IDs to report about
     pub tracked_call_ids: FxHashSet<CallId>,
     /// The allocation ids to report about.
     pub tracked_alloc_ids: FxHashSet<AllocId>,
     /// For the tracked alloc ids, also report read/write accesses.
     pub track_alloc_accesses: bool,
     /// Determine if data race detection should be enabled
     pub data_race_detector: bool,
     /// Determine if weak memory emulation should be enabled. Requires data race detection to be enabled
     pub weak_memory_emulation: bool,
     /// Track when an outdated (weak memory) load happens.
     pub track_outdated_loads: bool,
     /// Rate of spurious failures for compare_exchange_weak atomic operations,
     /// between 0.0 and 1.0, defaulting to 0.8 (80% chance of failure).
     pub cmpxchg_weak_failure_rate: f64,
     /// If `Some`, enable the `measureme` profiler, writing results to a file
     /// with the specified prefix.
     pub measureme_out: Option<String>,
     /// Panic when unsupported functionality is encountered.
     pub panic_on_unsupported: bool,
     /// Which style to use for printing backtraces.
     pub backtrace_style: BacktraceStyle,
     /// Which provenance to use for int2ptr casts
     pub provenance_mode: ProvenanceMode,
     /// Whether to ignore any output by the program. This is helpful when debugging miri
     /// as its messages don't get intermingled with the program messages.
     pub mute_stdout_stderr: bool,
     /// The probability of the active thread being preempted at the end of each basic block.
     pub preemption_rate: f64,
     /// Report the current instruction being executed every N basic blocks.
     pub report_progress: Option<u32>,
     /// Whether Stacked Borrows and Tree Borrows retagging should recurse into fields of datatypes.
     pub retag_fields: RetagFields,
     /// The location of a shared object file to load when calling external functions
     /// FIXME! consider allowing users to specify paths to multiple SO files, or to a directory
     pub external_so_file: Option<PathBuf>,
     /// Run a garbage collector for BorTags every N basic blocks.
     pub gc_interval: u32,
     /// The number of CPUs to be reported by miri.
     pub num_cpus: u32,
     /// Requires Miri to emulate pages of a certain size
     pub page_size: Option<u64>,
     /// Whether to collect a backtrace when each allocation is created, just in case it leaks.
     pub collect_leak_backtraces: bool,
 }

 impl Default for MiriConfig {
     fn default() -> MiriConfig {
         MiriConfig {
             env: vec![],
             validate: true,
             borrow_tracker: Some(BorrowTrackerMethod::StackedBorrows),
             unique_is_unique: false,
             check_alignment: AlignmentCheck::Int,
             isolated_op: IsolatedOp::Reject(RejectOpWith::Abort),
             ignore_leaks: false,
             forwarded_env_vars: vec![],
             args: vec![],
             seed: None,
             tracked_pointer_tags: FxHashSet::default(),
             tracked_call_ids: FxHashSet::default(),
             tracked_alloc_ids: FxHashSet::default(),
             track_alloc_accesses: false,
             data_race_detector: true,
             weak_memory_emulation: true,
             track_outdated_loads: false,
             cmpxchg_weak_failure_rate: 0.8, // 80%
             measureme_out: None,
             panic_on_unsupported: false,
             backtrace_style: BacktraceStyle::Short,
             provenance_mode: ProvenanceMode::Default,
             mute_stdout_stderr: false,
             preemption_rate: 0.01, // 1%
             report_progress: None,
             retag_fields: RetagFields::Yes,
             external_so_file: None,
             gc_interval: 10_000,
             num_cpus: 1,
             page_size: None,
             collect_leak_backtraces: true,
         }
     }
 }

 /// The state of the main thread. Implementation detail of `on_main_stack_empty`.
 #[derive(Default, Debug)]
 enum MainThreadState {
     #[default]
     Running,
     TlsDtors(tls::TlsDtorsState),
     Yield {
         remaining: u32,
     },
     Done,
 }

 impl MainThreadState {
     fn on_main_stack_empty<'tcx>(
         &mut self,
         this: &mut MiriInterpCx<'_, 'tcx>,
     ) -> InterpResult<'tcx, Poll<()>> {
         use MainThreadState::*;
         match self {
             Running => {
                 *self = TlsDtors(Default::default());
             }
             TlsDtors(state) =>
                 match state.on_stack_empty(this)? {
                     Poll::Pending => {} // just keep going
                     Poll::Ready(()) => {
                         // Give background threads a chance to finish by yielding the main thread a
                         // couple of times -- but only if we would also preempt threads randomly.
                         if this.machine.preemption_rate > 0.0 {
                             // There is a non-zero chance they will yield back to us often enough to
                             // make Miri terminate eventually.
                             *self = Yield { remaining: MAIN_THREAD_YIELDS_AT_SHUTDOWN };
                         } else {
                             // The other threads did not get preempted, so no need to yield back to
                             // them.
                             *self = Done;
                         }
                     }
                 },
             Yield { remaining } =>
                 match remaining.checked_sub(1) {
                     None => *self = Done,
                     Some(new_remaining) => {
                         *remaining = new_remaining;
                         this.yield_active_thread();
                     }
                 },
             Done => {
                 // Figure out exit code.
                 let ret_place = this.machine.main_fn_ret_place.clone().unwrap();
                 let exit_code = this.read_target_isize(&ret_place)?;
                 // Deal with our thread-local memory. We do *not* want to actually free it, instead we consider TLS
                 // to be like a global `static`, so that all memory reached by it is considered to "not leak".
                 this.terminate_active_thread(TlsAllocAction::Leak)?;
                 // Stop interpreter loop.
                 throw_machine_stop!(TerminationInfo::Exit { code: exit_code, leak_check: true });
             }
         }
         Ok(Poll::Pending)
     }
 }

 /// Returns a freshly created `InterpCx`.
 /// Public because this is also used by `priroda`.
 pub fn create_ecx<'mir, 'tcx: 'mir>(
     tcx: TyCtxt<'tcx>,
     entry_id: DefId,
     entry_type: EntryFnType,
     config: &MiriConfig,
 ) -> InterpResult<'tcx, InterpCx<'mir, 'tcx, MiriMachine<'mir, 'tcx>>> {
     let param_env = ty::ParamEnv::reveal_all();
     let layout_cx = LayoutCx { tcx, param_env };
     let mut ecx =
         InterpCx::new(tcx, rustc_span::DUMMY_SP, param_env, MiriMachine::new(config, layout_cx));

     // Some parts of initialization require a full `InterpCx`.
     MiriMachine::late_init(&mut ecx, config, {
         let mut state = MainThreadState::default();
         // Cannot capture anything GC-relevant here.
         Box::new(move |m| state.on_main_stack_empty(m))
     })?;

     // Make sure we have MIR. We check MIR for some stable monomorphic function in libcore.
     let sentinel = ecx.try_resolve_path(&["core", "ascii", "escape_default"], Namespace::ValueNS);
     if !matches!(sentinel, Some(s) if tcx.is_mir_available(s.def.def_id())) {
         tcx.dcx().fatal(
             "the current sysroot was built without `-Zalways-encode-mir`, or libcore seems missing. \
             Use `cargo miri setup` to prepare a sysroot that is suitable for Miri."
         );
     }

     // Setup first stack frame.
     let entry_instance = ty::Instance::mono(tcx, entry_id);

     // First argument is constructed later, because it's skipped if the entry function uses #[start].

     // Second argument (argc): length of `config.args`.
     let argc = Scalar::from_target_usize(u64::try_from(config.args.len()).unwrap(), &ecx);
     // Third argument (`argv`): created from `config.args`.
     let argv = {
         // Put each argument in memory, collect pointers.
         let mut argvs = Vec::<Immediate<Provenance>>::with_capacity(config.args.len());
         for arg in config.args.iter() {
             // Make space for `0` terminator.
             let size = u64::try_from(arg.len()).unwrap().checked_add(1).unwrap();
             let arg_type = Ty::new_array(tcx, tcx.types.u8, size);
             let arg_place =
                 ecx.allocate(ecx.layout_of(arg_type)?, MiriMemoryKind::Machine.into())?;
             ecx.write_os_str_to_c_str(OsStr::new(arg), arg_place.ptr(), size)?;
             ecx.mark_immutable(&arg_place);
             argvs.push(arg_place.to_ref(&ecx));
         }
         // Make an array with all these pointers, in the Miri memory.
         let argvs_layout = ecx.layout_of(Ty::new_array(
             tcx,
             Ty::new_imm_ptr(tcx, tcx.types.u8),
             u64::try_from(argvs.len()).unwrap(),
         ))?;
         let argvs_place = ecx.allocate(argvs_layout, MiriMemoryKind::Machine.into())?;
         for (idx, arg) in argvs.into_iter().enumerate() {
             let place = ecx.project_field(&argvs_place, idx)?;
             ecx.write_immediate(arg, &place)?;
         }
         ecx.mark_immutable(&argvs_place);
         // A pointer to that place is the 3rd argument for main.
         let argv = argvs_place.to_ref(&ecx);
         // Store `argc` and `argv` for macOS `_NSGetArg{c,v}`.
         {
             let argc_place =
                 ecx.allocate(ecx.machine.layouts.isize, MiriMemoryKind::Machine.into())?;
             ecx.write_scalar(argc, &argc_place)?;
             ecx.mark_immutable(&argc_place);
             ecx.machine.argc = Some(argc_place.ptr());

             let argv_place = ecx.allocate(
                 ecx.layout_of(Ty::new_imm_ptr(tcx, tcx.types.unit))?,
                 MiriMemoryKind::Machine.into(),
             )?;
             ecx.write_immediate(argv, &argv_place)?;
             ecx.mark_immutable(&argv_place);
             ecx.machine.argv = Some(argv_place.ptr());
         }
         // Store command line as UTF-16 for Windows `GetCommandLineW`.
         {
             // Construct a command string with all the arguments.
             let cmd_utf16: Vec<u16> = args_to_utf16_command_string(config.args.iter());

             let cmd_type =
                 Ty::new_array(tcx, tcx.types.u16, u64::try_from(cmd_utf16.len()).unwrap());
             let cmd_place =
                 ecx.allocate(ecx.layout_of(cmd_type)?, MiriMemoryKind::Machine.into())?;
             ecx.machine.cmd_line = Some(cmd_place.ptr());
             // Store the UTF-16 string. We just allocated so we know the bounds are fine.
             for (idx, &c) in cmd_utf16.iter().enumerate() {
                 let place = ecx.project_field(&cmd_place, idx)?;
                 ecx.write_scalar(Scalar::from_u16(c), &place)?;
             }
             ecx.mark_immutable(&cmd_place);
         }
         argv
     };

     // Return place (in static memory so that it does not count as leak).
     let ret_place = ecx.allocate(ecx.machine.layouts.isize, MiriMemoryKind::Machine.into())?;
     ecx.machine.main_fn_ret_place = Some(ret_place.clone());
     // Call start function.

     match entry_type {
         EntryFnType::Main { .. } => {
             let start_id = tcx.lang_items().start_fn().unwrap_or_else(|| {
                 tcx.dcx().fatal(
                     "could not find start function. Make sure the entry point is marked with `#[start]`."
                 );
             });
             let main_ret_ty = tcx.fn_sig(entry_id).no_bound_vars().unwrap().output();
             let main_ret_ty = main_ret_ty.no_bound_vars().unwrap();
             let start_instance = ty::Instance::resolve(
                 tcx,
                 ty::ParamEnv::reveal_all(),
                 start_id,
                 tcx.mk_args(&[ty::GenericArg::from(main_ret_ty)]),
             )
             .unwrap()
             .unwrap();

             let main_ptr = ecx.fn_ptr(FnVal::Instance(entry_instance));

             // Inlining of `DEFAULT` from
             // https://github.com/rust-lang/rust/blob/master/compiler/rustc_session/src/config/sigpipe.rs.
             // Always using DEFAULT is okay since we don't support signals in Miri anyway.
             let sigpipe = 2;

             ecx.call_function(
                 start_instance,
                 Abi::Rust,
                 &[
                     Scalar::from_pointer(main_ptr, &ecx).into(),
                     argc.into(),
                     argv,
                     Scalar::from_u8(sigpipe).into(),
                 ],
                 Some(&ret_place),
                 StackPopCleanup::Root { cleanup: true },
             )?;
         }
         EntryFnType::Start => {
             ecx.call_function(
                 entry_instance,
                 Abi::Rust,
                 &[argc.into(), argv],
                 Some(&ret_place),
                 StackPopCleanup::Root { cleanup: true },
             )?;
         }
     }

     Ok(ecx)
 }

 /// Evaluates the entry function specified by `entry_id`.
 /// Returns `Some(return_code)` if program executed completed.
 /// Returns `None` if an evaluation error occurred.
 #[allow(clippy::needless_lifetimes)]
 pub fn eval_entry<'tcx>(
     tcx: TyCtxt<'tcx>,
     entry_id: DefId,
     entry_type: EntryFnType,
     config: MiriConfig,
 ) -> Option<i64> {
     // Copy setting before we move `config`.
     let ignore_leaks = config.ignore_leaks;

     let mut ecx = match create_ecx(tcx, entry_id, entry_type, &config) {
         Ok(v) => v,
         Err(err) => {
             let (kind, backtrace) = err.into_parts();
             backtrace.print_backtrace();
             panic!("Miri initialization error: {kind:?}")
         }
     };

     // Perform the main execution.
     let res: thread::Result<InterpResult<'_, !>> =
         panic::catch_unwind(AssertUnwindSafe(|| ecx.run_threads()));
     let res = res.unwrap_or_else(|panic_payload| {
         ecx.handle_ice();
         panic::resume_unwind(panic_payload)
     });
     let res = match res {
         Err(res) => res,
         // `Ok` can never happen
         Ok(never) => match never {},
     };

     // Machine cleanup. Only do this if all threads have terminated; threads that are still running
     // might cause Stacked Borrows errors (https://github.com/rust-lang/miri/issues/2396).
     if ecx.have_all_terminated() {
         // Even if all threads have terminated, we have to beware of data races since some threads
         // might not have joined the main thread (https://github.com/rust-lang/miri/issues/2020,
         // https://github.com/rust-lang/miri/issues/2508).
         ecx.allow_data_races_all_threads_done();
         EnvVars::cleanup(&mut ecx).expect("error during env var cleanup");
     }

     // Process the result.
     let (return_code, leak_check) = report_error(&ecx, res)?;
     if leak_check && !ignore_leaks {
         // Check for thread leaks.
         if !ecx.have_all_terminated() {
             tcx.dcx().err("the main thread terminated without waiting for all remaining threads");
             tcx.dcx().note("pass `-Zmiri-ignore-leaks` to disable this check");
             return None;
         }
         // Check for memory leaks.
         info!("Additional static roots: {:?}", ecx.machine.static_roots);
         let leaks = ecx.find_leaked_allocations(&ecx.machine.static_roots);
         if !leaks.is_empty() {
             report_leaks(&ecx, leaks);
             let leak_message = "the evaluated program leaked memory, pass `-Zmiri-ignore-leaks` to disable this check";
             if ecx.machine.collect_leak_backtraces {
                 // If we are collecting leak backtraces, each leak is a distinct error diagnostic.
                 tcx.dcx().note(leak_message);
             } else {
                 // If we do not have backtraces, we just report an error without any span.
                 tcx.dcx().err(leak_message);
             };
             // Ignore the provided return code - let the reported error
             // determine the return code.
             return None;
         }
     }
     Some(return_code)
 }

 /// Turns an array of arguments into a Windows command line string.
 ///
 /// The string will be UTF-16 encoded and NUL terminated.
 ///
 /// Panics if the zeroth argument contains the `"` character because doublequotes
 /// in `argv[0]` cannot be encoded using the standard command line parsing rules.
 ///
 /// Further reading:
 /// * [Parsing C++ command-line arguments](https://docs.microsoft.com/en-us/cpp/cpp/main-function-command-line-args?view=msvc-160#parsing-c-command-line-arguments)
 /// * [The C/C++ Parameter Parsing Rules](https://daviddeley.com/autohotkey/parameters/parameters.htm#WINCRULES)
 fn args_to_utf16_command_string<I, T>(mut args: I) -> Vec<u16>
 where
     I: Iterator<Item = T>,
     T: AsRef<str>,
 {
     // Parse argv[0]. Slashes aren't escaped. Literal double quotes are not allowed.
     let mut cmd = {
         let arg0 = if let Some(arg0) = args.next() {
             arg0
         } else {
             return vec![0];
         };
         let arg0 = arg0.as_ref();
         if arg0.contains('"') {
             panic!("argv[0] cannot contain a doublequote (\") character");
         } else {
             // Always surround argv[0] with quotes.
             let mut s = String::new();
             s.push('"');
             s.push_str(arg0);
             s.push('"');
             s
         }
     };

     // Build the other arguments.
     for arg in args {
         let arg = arg.as_ref();
         cmd.push(' ');
         if arg.is_empty() {
             cmd.push_str("\"\"");
         } else if !arg.bytes().any(|c| matches!(c, b'"' | b'\t' | b' ')) {
             // No quote, tab, or space -- no escaping required.
             cmd.push_str(arg);
         } else {
             // Spaces and tabs are escaped by surrounding them in quotes.
             // Quotes are themselves escaped by using backslashes when in a
             // quoted block.
             // Backslashes only need to be escaped when one or more are directly
             // followed by a quote. Otherwise they are taken literally.

             cmd.push('"');
             let mut chars = arg.chars().peekable();
             loop {
                 let mut nslashes = 0;
                 while let Some(&'\\') = chars.peek() {
                     chars.next();
                     nslashes += 1;
                 }

                 match chars.next() {
                     Some('"') => {
                         cmd.extend(iter::repeat('\\').take(nslashes * 2 + 1));
                         cmd.push('"');
                     }
                     Some(c) => {
                         cmd.extend(iter::repeat('\\').take(nslashes));
                         cmd.push(c);
                     }
                     None => {
                         cmd.extend(iter::repeat('\\').take(nslashes * 2));
                         break;
                     }
                 }
             }
             cmd.push('"');
         }
     }

     if cmd.contains('\0') {
         panic!("interior null in command line arguments");
     }
     cmd.encode_utf16().chain(iter::once(0)).collect()
 }

 #[cfg(test)]
 mod tests {
     use super::*;
     #[test]
     #[should_panic(expected = "argv[0] cannot contain a doublequote (\") character")]
     fn windows_argv0_panic_on_quote() {
         args_to_utf16_command_string(["\""].iter());
     }
     #[test]
     fn windows_argv0_no_escape() {
         // Ensure that a trailing backslash in argv[0] is not escaped.
         let cmd = String::from_utf16_lossy(&args_to_utf16_command_string(
             [r"C:\Program Files\", "arg1", "arg 2", "arg \" 3"].iter(),
         ));
         assert_eq!(cmd.trim_end_matches('\0'), r#""C:\Program Files\" arg1 "arg 2" "arg \" 3""#);
     }
 }
	//! Main evaluator loop and setting up the initial stack frame.

	use std::ffi::{OsStr, OsString};
	use std::iter;
	use std::panic::{self, AssertUnwindSafe};
	use std::path::PathBuf;
	use std::task::Poll;
	use std::thread;

	use crate::concurrency::thread::TlsAllocAction;
	use crate::diagnostics::report_leaks;
	use rustc_data_structures::fx::FxHashSet;
	use rustc_hir::def::Namespace;
	use rustc_hir::def_id::DefId;
	use rustc_middle::ty::{
	self,
	layout::{LayoutCx, LayoutOf},
	Ty, TyCtxt,
	};
	use rustc_target::spec::abi::Abi;

	use rustc_session::config::EntryFnType;

	use crate::shims::tls;
	use crate::*;

	/// When the main thread would exit, we will yield to any other thread that is ready to execute.
	/// But we must only do that a finite number of times, or a background thread running `loop {}`
	/// will hang the program.
	const MAIN_THREAD_YIELDS_AT_SHUTDOWN: u32 = 256;

	#[derive(Copy, Clone, Debug, PartialEq)]
	pub enum AlignmentCheck {
	/// Do not check alignment.
	None,
	/// Check alignment "symbolically", i.e., using only the requested alignment for an allocation and not its real base address.
	Symbolic,
	/// Check alignment on the actual physical integer address.
	Int,
	}

	#[derive(Copy, Clone, Debug, PartialEq)]
	pub enum RejectOpWith {
	/// Isolated op is rejected with an abort of the machine.
	Abort,

	/// If not Abort, miri returns an error for an isolated op.
	/// Following options determine if user should be warned about such error.
	/// Do not print warning about rejected isolated op.
	NoWarning,

	/// Print a warning about rejected isolated op, with backtrace.
	Warning,

	/// Print a warning about rejected isolated op, without backtrace.
	WarningWithoutBacktrace,
	}

	#[derive(Copy, Clone, Debug, PartialEq)]
	pub enum IsolatedOp {
	/// Reject an op requiring communication with the host. By
	/// default, miri rejects the op with an abort. If not, it returns
	/// an error code, and prints a warning about it. Warning levels
	/// are controlled by `RejectOpWith` enum.
	Reject(RejectOpWith),

	/// Execute op requiring communication with the host, i.e. disable isolation.
	Allow,
	}

	#[derive(Copy, Clone, PartialEq, Eq)]
	pub enum BacktraceStyle {
	/// Prints a terser backtrace which ideally only contains relevant information.
	Short,
	/// Prints a backtrace with all possible information.
	Full,
	/// Prints only the frame that the error occurs in.
	Off,
	}

	/// Configuration needed to spawn a Miri instance.
	#[derive(Clone)]
	pub struct MiriConfig {
	/// The host environment snapshot to use as basis for what is provided to the interpreted program.
	/// (This is still subject to isolation as well as `forwarded_env_vars`.)
	pub env: Vec<(OsString, OsString)>,
	/// Determine if validity checking is enabled.
	pub validate: bool,
	/// Determines if Stacked Borrows or Tree Borrows is enabled.
	pub borrow_tracker: Option<BorrowTrackerMethod>,
	/// Whether `core::ptr::Unique` receives special treatment.
	/// If `true` then `Unique` is reborrowed with its own new tag and permission,
	/// otherwise `Unique` is just another raw pointer.
	pub unique_is_unique: bool,
	/// Controls alignment checking.
	pub check_alignment: AlignmentCheck,
	/// Action for an op requiring communication with the host.
	pub isolated_op: IsolatedOp,
	/// Determines if memory leaks should be ignored.
	pub ignore_leaks: bool,
	/// Environment variables that should always be forwarded from the host.
	pub forwarded_env_vars: Vec<String>,
	/// Command-line arguments passed to the interpreted program.
	pub args: Vec<String>,
	/// The seed to use when non-determinism or randomness are required (e.g. ptr-to-int cast, `getrandom()`).
	pub seed: Option<u64>,
	/// The stacked borrows pointer ids to report about
	pub tracked_pointer_tags: FxHashSet<BorTag>,
	/// The stacked borrows call IDs to report about
	pub tracked_call_ids: FxHashSet<CallId>,
	/// The allocation ids to report about.
	pub tracked_alloc_ids: FxHashSet<AllocId>,
	/// For the tracked alloc ids, also report read/write accesses.
	pub track_alloc_accesses: bool,
	/// Determine if data race detection should be enabled
	pub data_race_detector: bool,
	/// Determine if weak memory emulation should be enabled. Requires data race detection to be enabled
	pub weak_memory_emulation: bool,
	/// Track when an outdated (weak memory) load happens.
	pub track_outdated_loads: bool,
	/// Rate of spurious failures for compare_exchange_weak atomic operations,
	/// between 0.0 and 1.0, defaulting to 0.8 (80% chance of failure).
	pub cmpxchg_weak_failure_rate: f64,
	/// If `Some`, enable the `measureme` profiler, writing results to a file
	/// with the specified prefix.
	pub measureme_out: Option<String>,
	/// Panic when unsupported functionality is encountered.
	pub panic_on_unsupported: bool,
	/// Which style to use for printing backtraces.
	pub backtrace_style: BacktraceStyle,
	/// Which provenance to use for int2ptr casts
	pub provenance_mode: ProvenanceMode,
	/// Whether to ignore any output by the program. This is helpful when debugging miri
	/// as its messages don't get intermingled with the program messages.
	pub mute_stdout_stderr: bool,
	/// The probability of the active thread being preempted at the end of each basic block.
	pub preemption_rate: f64,
	/// Report the current instruction being executed every N basic blocks.
	pub report_progress: Option<u32>,
	/// Whether Stacked Borrows and Tree Borrows retagging should recurse into fields of datatypes.
	pub retag_fields: RetagFields,
	/// The location of a shared object file to load when calling external functions
	/// FIXME! consider allowing users to specify paths to multiple SO files, or to a directory
	pub external_so_file: Option<PathBuf>,
	/// Run a garbage collector for BorTags every N basic blocks.
	pub gc_interval: u32,
	/// The number of CPUs to be reported by miri.
	pub num_cpus: u32,
	/// Requires Miri to emulate pages of a certain size
	pub page_size: Option<u64>,
	/// Whether to collect a backtrace when each allocation is created, just in case it leaks.
	pub collect_leak_backtraces: bool,
	}

	impl Default for MiriConfig {
	fn default() -> MiriConfig {
	MiriConfig {
	env: vec![],
	validate: true,
	borrow_tracker: Some(BorrowTrackerMethod::StackedBorrows),
	unique_is_unique: false,
	check_alignment: AlignmentCheck::Int,
	isolated_op: IsolatedOp::Reject(RejectOpWith::Abort),
	ignore_leaks: false,
	forwarded_env_vars: vec![],
	args: vec![],
	seed: None,
	tracked_pointer_tags: FxHashSet::default(),
	tracked_call_ids: FxHashSet::default(),
	tracked_alloc_ids: FxHashSet::default(),
	track_alloc_accesses: false,
	data_race_detector: true,
	weak_memory_emulation: true,
	track_outdated_loads: false,
	cmpxchg_weak_failure_rate: 0.8, // 80%
	measureme_out: None,
	panic_on_unsupported: false,
	backtrace_style: BacktraceStyle::Short,
	provenance_mode: ProvenanceMode::Default,
	mute_stdout_stderr: false,
	preemption_rate: 0.01, // 1%
	report_progress: None,
	retag_fields: RetagFields::Yes,
	external_so_file: None,
	gc_interval: 10_000,
	num_cpus: 1,
	page_size: None,
	collect_leak_backtraces: true,
	}
	}
	}

	/// The state of the main thread. Implementation detail of `on_main_stack_empty`.
	#[derive(Default, Debug)]
	enum MainThreadState {
	#[default]
	Running,
	TlsDtors(tls::TlsDtorsState),
	Yield {
	remaining: u32,
	},
	Done,
	}

	impl MainThreadState {
	fn on_main_stack_empty<'tcx>(
	&mut self,
	this: &mut MiriInterpCx<'_, 'tcx>,
	) -> InterpResult<'tcx, Poll<()>> {
	use MainThreadState::*;
	match self {
	Running => {
	*self = TlsDtors(Default::default());
	}
	TlsDtors(state) =>
	match state.on_stack_empty(this)? {
	Poll::Pending => {} // just keep going
	Poll::Ready(()) => {
	// Give background threads a chance to finish by yielding the main thread a
	// couple of times -- but only if we would also preempt threads randomly.
	if this.machine.preemption_rate > 0.0 {
	// There is a non-zero chance they will yield back to us often enough to
	// make Miri terminate eventually.
	*self = Yield { remaining: MAIN_THREAD_YIELDS_AT_SHUTDOWN };
	} else {
	// The other threads did not get preempted, so no need to yield back to
	// them.
	*self = Done;
	}
	}
	},
	Yield { remaining } =>
	match remaining.checked_sub(1) {
	None => *self = Done,
	Some(new_remaining) => {
	*remaining = new_remaining;
	this.yield_active_thread();
	}
	},
	Done => {
	// Figure out exit code.
	let ret_place = this.machine.main_fn_ret_place.clone().unwrap();
	let exit_code = this.read_target_isize(&ret_place)?;
	// Deal with our thread-local memory. We do not want to actually free it, instead we consider TLS
	// to be like a global `static`, so that all memory reached by it is considered to "not leak".
	this.terminate_active_thread(TlsAllocAction::Leak)?;
	// Stop interpreter loop.
	throw_machine_stop!(TerminationInfo::Exit { code: exit_code, leak_check: true });
	}
	}
	Ok(Poll::Pending)
	}
	}

	/// Returns a freshly created `InterpCx`.
	/// Public because this is also used by `priroda`.
	pub fn create_ecx<'mir, 'tcx: 'mir>(
	tcx: TyCtxt<'tcx>,
	entry_id: DefId,
	entry_type: EntryFnType,
	config: &MiriConfig,
	) -> InterpResult<'tcx, InterpCx<'mir, 'tcx, MiriMachine<'mir, 'tcx>>> {
	let param_env = ty::ParamEnv::reveal_all();
	let layout_cx = LayoutCx { tcx, param_env };
	let mut ecx =
	InterpCx::new(tcx, rustc_span::DUMMY_SP, param_env, MiriMachine::new(config, layout_cx));

	// Some parts of initialization require a full `InterpCx`.
	MiriMachine::late_init(&mut ecx, config, {
	let mut state = MainThreadState::default();
	// Cannot capture anything GC-relevant here.
	Box::new(move \|m\| state.on_main_stack_empty(m))
	})?;

	// Make sure we have MIR. We check MIR for some stable monomorphic function in libcore.
	let sentinel = ecx.try_resolve_path(&["core", "ascii", "escape_default"], Namespace::ValueNS);
	if !matches!(sentinel, Some(s) if tcx.is_mir_available(s.def.def_id())) {
	tcx.dcx().fatal(
	"the current sysroot was built without `-Zalways-encode-mir`, or libcore seems missing. \
	Use `cargo miri setup` to prepare a sysroot that is suitable for Miri."
	);
	}

	// Setup first stack frame.
	let entry_instance = ty::Instance::mono(tcx, entry_id);

	// First argument is constructed later, because it's skipped if the entry function uses #[start].

	// Second argument (argc): length of `config.args`.
	let argc = Scalar::from_target_usize(u64::try_from(config.args.len()).unwrap(), &ecx);
	// Third argument (`argv`): created from `config.args`.
	let argv = {
	// Put each argument in memory, collect pointers.
	let mut argvs = Vec::<Immediate<Provenance>>::with_capacity(config.args.len());
	for arg in config.args.iter() {
	// Make space for `0` terminator.
	let size = u64::try_from(arg.len()).unwrap().checked_add(1).unwrap();
	let arg_type = Ty::new_array(tcx, tcx.types.u8, size);
	let arg_place =
	ecx.allocate(ecx.layout_of(arg_type)?, MiriMemoryKind::Machine.into())?;
	ecx.write_os_str_to_c_str(OsStr::new(arg), arg_place.ptr(), size)?;
	ecx.mark_immutable(&arg_place);
	argvs.push(arg_place.to_ref(&ecx));
	}
	// Make an array with all these pointers, in the Miri memory.
	let argvs_layout = ecx.layout_of(Ty::new_array(
	tcx,
	Ty::new_imm_ptr(tcx, tcx.types.u8),
	u64::try_from(argvs.len()).unwrap(),
	))?;
	let argvs_place = ecx.allocate(argvs_layout, MiriMemoryKind::Machine.into())?;
	for (idx, arg) in argvs.into_iter().enumerate() {
	let place = ecx.project_field(&argvs_place, idx)?;
	ecx.write_immediate(arg, &place)?;
	}
	ecx.mark_immutable(&argvs_place);
	// A pointer to that place is the 3rd argument for main.
	let argv = argvs_place.to_ref(&ecx);
	// Store `argc` and `argv` for macOS `_NSGetArg{c,v}`.
	{
	let argc_place =
	ecx.allocate(ecx.machine.layouts.isize, MiriMemoryKind::Machine.into())?;
	ecx.write_scalar(argc, &argc_place)?;
	ecx.mark_immutable(&argc_place);
	ecx.machine.argc = Some(argc_place.ptr());

	let argv_place = ecx.allocate(
	ecx.layout_of(Ty::new_imm_ptr(tcx, tcx.types.unit))?,
	MiriMemoryKind::Machine.into(),
	)?;
	ecx.write_immediate(argv, &argv_place)?;
	ecx.mark_immutable(&argv_place);
	ecx.machine.argv = Some(argv_place.ptr());
	}
	// Store command line as UTF-16 for Windows `GetCommandLineW`.
	{
	// Construct a command string with all the arguments.
	let cmd_utf16: Vec<u16> = args_to_utf16_command_string(config.args.iter());

	let cmd_type =
	Ty::new_array(tcx, tcx.types.u16, u64::try_from(cmd_utf16.len()).unwrap());
	let cmd_place =
	ecx.allocate(ecx.layout_of(cmd_type)?, MiriMemoryKind::Machine.into())?;
	ecx.machine.cmd_line = Some(cmd_place.ptr());
	// Store the UTF-16 string. We just allocated so we know the bounds are fine.
	for (idx, &c) in cmd_utf16.iter().enumerate() {
	let place = ecx.project_field(&cmd_place, idx)?;
	ecx.write_scalar(Scalar::from_u16(c), &place)?;
	}
	ecx.mark_immutable(&cmd_place);
	}
	argv
	};

	// Return place (in static memory so that it does not count as leak).
	let ret_place = ecx.allocate(ecx.machine.layouts.isize, MiriMemoryKind::Machine.into())?;
	ecx.machine.main_fn_ret_place = Some(ret_place.clone());
	// Call start function.

	match entry_type {
	EntryFnType::Main { .. } => {
	let start_id = tcx.lang_items().start_fn().unwrap_or_else(\|\| {
	tcx.dcx().fatal(
	"could not find start function. Make sure the entry point is marked with `#[start]`."
	);
	});
	let main_ret_ty = tcx.fn_sig(entry_id).no_bound_vars().unwrap().output();
	let main_ret_ty = main_ret_ty.no_bound_vars().unwrap();
	let start_instance = ty::Instance::resolve(
	tcx,
	ty::ParamEnv::reveal_all(),
	start_id,
	tcx.mk_args(&[ty::GenericArg::from(main_ret_ty)]),
	)
	.unwrap()
	.unwrap();

	let main_ptr = ecx.fn_ptr(FnVal::Instance(entry_instance));

	// Inlining of `DEFAULT` from
	// https://github.com/rust-lang/rust/blob/master/compiler/rustc_session/src/config/sigpipe.rs.
	// Always using DEFAULT is okay since we don't support signals in Miri anyway.
	let sigpipe = 2;

	ecx.call_function(
	start_instance,
	Abi::Rust,
	&[
	Scalar::from_pointer(main_ptr, &ecx).into(),
	argc.into(),
	argv,
	Scalar::from_u8(sigpipe).into(),
	],
	Some(&ret_place),
	StackPopCleanup::Root { cleanup: true },
	)?;
	}
	EntryFnType::Start => {
	ecx.call_function(
	entry_instance,
	Abi::Rust,
	&[argc.into(), argv],
	Some(&ret_place),
	StackPopCleanup::Root { cleanup: true },
	)?;
	}
	}

	Ok(ecx)
	}

	/// Evaluates the entry function specified by `entry_id`.
	/// Returns `Some(return_code)` if program executed completed.
	/// Returns `None` if an evaluation error occurred.
	#[allow(clippy::needless_lifetimes)]
	pub fn eval_entry<'tcx>(
	tcx: TyCtxt<'tcx>,
	entry_id: DefId,
	entry_type: EntryFnType,
	config: MiriConfig,
	) -> Option<i64> {
	// Copy setting before we move `config`.
	let ignore_leaks = config.ignore_leaks;

	let mut ecx = match create_ecx(tcx, entry_id, entry_type, &config) {
	Ok(v) => v,
	Err(err) => {
	let (kind, backtrace) = err.into_parts();
	backtrace.print_backtrace();
	panic!("Miri initialization error: {kind:?}")
	}
	};

	// Perform the main execution.
	let res: thread::Result<InterpResult<'_, !>> =
	panic::catch_unwind(AssertUnwindSafe(\|\| ecx.run_threads()));
	let res = res.unwrap_or_else(\|panic_payload\| {
	ecx.handle_ice();
	panic::resume_unwind(panic_payload)
	});
	let res = match res {
	Err(res) => res,
	// `Ok` can never happen
	Ok(never) => match never {},
	};

	// Machine cleanup. Only do this if all threads have terminated; threads that are still running
	// might cause Stacked Borrows errors (https://github.com/rust-lang/miri/issues/2396).
	if ecx.have_all_terminated() {
	// Even if all threads have terminated, we have to beware of data races since some threads
	// might not have joined the main thread (https://github.com/rust-lang/miri/issues/2020,
	// https://github.com/rust-lang/miri/issues/2508).
	ecx.allow_data_races_all_threads_done();
	EnvVars::cleanup(&mut ecx).expect("error during env var cleanup");
	}

	// Process the result.
	let (return_code, leak_check) = report_error(&ecx, res)?;
	if leak_check && !ignore_leaks {
	// Check for thread leaks.
	if !ecx.have_all_terminated() {
	tcx.dcx().err("the main thread terminated without waiting for all remaining threads");
	tcx.dcx().note("pass `-Zmiri-ignore-leaks` to disable this check");
	return None;
	}
	// Check for memory leaks.
	info!("Additional static roots: {:?}", ecx.machine.static_roots);
	let leaks = ecx.find_leaked_allocations(&ecx.machine.static_roots);
	if !leaks.is_empty() {
	report_leaks(&ecx, leaks);
	let leak_message = "the evaluated program leaked memory, pass `-Zmiri-ignore-leaks` to disable this check";
	if ecx.machine.collect_leak_backtraces {
	// If we are collecting leak backtraces, each leak is a distinct error diagnostic.
	tcx.dcx().note(leak_message);
	} else {
	// If we do not have backtraces, we just report an error without any span.
	tcx.dcx().err(leak_message);
	};
	// Ignore the provided return code - let the reported error
	// determine the return code.
	return None;
	}
	}
	Some(return_code)
	}

	/// Turns an array of arguments into a Windows command line string.
	///
	/// The string will be UTF-16 encoded and NUL terminated.
	///
	/// Panics if the zeroth argument contains the `"` character because doublequotes
	/// in `argv[0]` cannot be encoded using the standard command line parsing rules.
	///
	/// Further reading:
	/// * [Parsing C++ command-line arguments](https://docs.microsoft.com/en-us/cpp/cpp/main-function-command-line-args?view=msvc-160#parsing-c-command-line-arguments)
	/// * [The C/C++ Parameter Parsing Rules](https://daviddeley.com/autohotkey/parameters/parameters.htm#WINCRULES)
	fn args_to_utf16_command_string<I, T>(mut args: I) -> Vec<u16>
	where
	I: Iterator<Item = T>,
	T: AsRef<str>,
	{
	// Parse argv[0]. Slashes aren't escaped. Literal double quotes are not allowed.
	let mut cmd = {
	let arg0 = if let Some(arg0) = args.next() {
	arg0
	} else {
	return vec![0];
	};
	let arg0 = arg0.as_ref();
	if arg0.contains('"') {
	panic!("argv[0] cannot contain a doublequote (\") character");
	} else {
	// Always surround argv[0] with quotes.
	let mut s = String::new();
	s.push('"');
	s.push_str(arg0);
	s.push('"');
	s
	}
	};

	// Build the other arguments.
	for arg in args {
	let arg = arg.as_ref();
	cmd.push(' ');
	if arg.is_empty() {
	cmd.push_str("\"\"");
	} else if !arg.bytes().any(\|c\| matches!(c, b'"' \| b'\t' \| b' ')) {
	// No quote, tab, or space -- no escaping required.
	cmd.push_str(arg);
	} else {
	// Spaces and tabs are escaped by surrounding them in quotes.
	// Quotes are themselves escaped by using backslashes when in a
	// quoted block.
	// Backslashes only need to be escaped when one or more are directly
	// followed by a quote. Otherwise they are taken literally.

	cmd.push('"');
	let mut chars = arg.chars().peekable();
	loop {
	let mut nslashes = 0;
	while let Some(&'\\') = chars.peek() {
	chars.next();
	nslashes += 1;
	}

	match chars.next() {
	Some('"') => {
	cmd.extend(iter::repeat('\\').take(nslashes * 2 + 1));
	cmd.push('"');
	}
	Some(c) => {
	cmd.extend(iter::repeat('\\').take(nslashes));
	cmd.push(c);
	}
	None => {
	cmd.extend(iter::repeat('\\').take(nslashes * 2));
	break;
	}
	}
	}
	cmd.push('"');
	}
	}

	if cmd.contains('\0') {
	panic!("interior null in command line arguments");
	}
	cmd.encode_utf16().chain(iter::once(0)).collect()
	}

	#[cfg(test)]
	mod tests {
	use super::*;
	#[test]
	#[should_panic(expected = "argv[0] cannot contain a doublequote (\") character")]
	fn windows_argv0_panic_on_quote() {
	args_to_utf16_command_string(["\""].iter());
	}
	#[test]
	fn windows_argv0_no_escape() {
	// Ensure that a trailing backslash in argv[0] is not escaped.
	let cmd = String::from_utf16_lossy(&args_to_utf16_command_string(
	[r"C:\Program Files\", "arg1", "arg 2", "arg \" 3"].iter(),
	));
	assert_eq!(cmd.trim_end_matches('\0'), r#""C:\Program Files\" arg1 "arg 2" "arg \" 3""#);
	}
	}